Nonlinear Modelling for Time-Varying Water Temperature PID Control

2021 IEEE 17th International Colloquium on Signal Processing & Its Applications (CSPA) Pub Date : 2021-03-05 DOI:10.1109/CSPA52141.2021.9377296

Muhamad Danial Mohammad Shah, Nurul Nadia Mohammad, N. Hambali

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引用次数: 3

Abstract

This paper is proposed to model and control the water temperature of Steam Distillation Pilot Plant (SDPP) using nonlinear modelling and PID control, respectively. Pseudo Random Binary Sequence (PRBS) and Multi-Sine (M-Sine) have been implemented to this system to perturb the input of the process and excite the nonlinearity behaviour of system dynamic. The Nonlinear Auto Regressive with Exogenous Input (NARX) model structure was used to estimate and validate the temperature output model of SDPP. The best transfer function model was chosen from the simulated result of different NARX model structures based on high percentage of fitness, low value of final prediction error and the mean square error. Later, a PID controller was designed using Ziegler-Nichols and Cohen Coon tuning methods. The results presented that the Ziegler-Nichols tuning method demonstrated better performance than Cohen Coon for PRBS input in terms of rise time (Tr), settling time (Ts) and integral square error (ISE) values while Cohen Coon tuning method showed better performance compared with Ziegler-Nichols for M-Sine input based on Tr, percent overshoot (%OS) and ISE values.

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时变水温PID控制的非线性建模

提出了用非线性建模和PID控制分别对蒸汽蒸馏中试装置(SDPP)的水温进行建模和控制。该系统采用伪随机二值序列(PRBS)和多重正弦(m - sin)对过程的输入进行扰动，激发系统动态的非线性行为。采用带外源输入的非线性自回归(NARX)模型结构对SDPP的温度输出模型进行估计和验证。基于高适应度百分比、低最终预测误差值和均方误差，从不同NARX模型结构的模拟结果中选择最佳传递函数模型。随后，采用Ziegler-Nichols和Cohen Coon整定方法设计了PID控制器。结果表明，对于PRBS输入，Ziegler-Nichols调谐方法在上升时间(Tr)、稳定时间(Ts)和积分平方误差(ISE)值方面表现优于Cohen Coon，而对于M-Sine输入，基于Tr、超调百分比(%OS)和ISE值，Cohen Coon调谐方法表现优于Ziegler-Nichols。

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来源期刊

2021 IEEE 17th International Colloquium on Signal Processing & Its Applications (CSPA)

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